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During SPURT (Spurenstofftransport in der Tropopausenregion, trace gas transport in the tropopause region) we performed measurements of a wide range of trace gases with different lifetimes and sink/source characteristics in the northern hemispheric upper troposphere (UT) and lowermost stratosphere (LMS). A large number of in-situ instruments were deployed on board a Learjet 35A, flying at altitudes up to 13.7 km, at times reaching to nearly 380 K potential temperature. Eight measurement campaigns (consisting of a total of 36 flights), distributed over all seasons and typically covering latitudes between 35° N and 75° N in the European longitude sector (10° W–20° E), were performed. Here we present an overview of the project, describing the instrumentation, the encountered meteorological situations during the campaigns and the data set available from SPURT. Measurements were obtained for N2O, CH4, CO, CO2, CFC12, H2, SF6, NO, NOy, O3 and H2O. We illustrate the strength of this new data set by showing mean distributions of the mixing ratios of selected trace gases, using a potential temperature – equivalent latitude coordinate system. The observations reveal that the LMS is most stratospheric in character during spring, with the highest mixing ratios of O3 and NOy and the lowest mixing ratios of N2O and SF6. The lowest mixing ratios of NOy and O3 are observed during autumn, together with the highest mixing ratios of N2O and SF6 indicating a strong tropospheric influence. For H2O, however, the maximum concentrations in the LMS are found during summer, suggesting unique (temperature- and convection-controlled) conditions for this molecule during transport across the tropopause. The SPURT data set is presently the most accurate and complete data set for many trace species in the LMS, and its main value is the simultaneous measurement of a suite of trace gases having different lifetimes and physical-chemical histories. It is thus very well suited for studies of atmospheric transport, for model validation, and for investigations of seasonal changes in the UT/LMS, as demonstrated in accompanying and elsewhere published studies.
On the observation of mesospheric air inside the arctic stratospheric polar vortex in early 2003
(2005)
During several balloon flights inside the Arctic polar vortex in early 2003, unusual trace gas distributions were observed, which indicate a strong influence of mesospheric air in the stratosphere. The tuneable diode laser (TDL) instrument SPIRALE (Spectroscopie InFrarouge par Absorption de Lasers Embarqués) measured unusually high CO values (up to 600 ppb) on 27 January at about 30 km altitude. The cryosampler BONBON sampled air masses with very high molecular Hydrogen, extremely low SF6 and enhanced CO values on 6 March at about 25 km altitude. Finally, the MIPAS (Michelson Interferometer for Passive Atmospheric Sounding) Fourier Transform Infra-Red (FTIR) spectrometer showed NOy values which are significantly higher than NOy* (the NOy derived from a correlation between N2O and NOy under undisturbed conditions), on 21 and 22 March in a layer centred at 22 km altitude. Thus, the mesospheric air seems to have been present in a layer descending from about 30 km in late January to 25 km altitude in early March and about 22 km altitude on 20 March. We present corroborating evidence from a model study using the KASIMA (KArlsruhe Simulation model of the Middle Atmosphere) model that also shows a layer of mesospheric air, which descended into the stratosphere in November and early December 2002, before the minor warming which occurred in late December 2002 lead to a descent of upper stratospheric air, cutting of a layer in which mesospheric air is present. This layer then descended inside the vortex over the course of the winter. The same feature is found in trajectory calculations, based on a large number of trajectories started in the vicinity of the observations on 6 March. Based on the difference between the mean age derived from SF6 (which has an irreversible mesospheric loss) and from CO2 (whose mesospheric loss is much smaller and reversible) we estimate that the fraction of mesospheric air in the layer observed on 6 March, must have been somewhere between 35% and 100%.
Im Rahmen des Projektes SPURT (Spurenstofftransport in der Tropopausenregion) als Teil des deutschen Atmosphärenforschungsprogramms AFO 2000 wurden bei 8 Messkampagnen mit insgesamt 36 Flügen innerhalb eines Beobachtungszeitraums von zwei Jahren (Nov. 2001 bis Juli 2003) Spurengasmessungen in dem Breitenbereich zwischen 35°N und 75°N durchgeführt. Für die Messungen der Spurengase N2O, F12, SF6, H2 und CO wurde der vollautomatisierte in-situ GC (Gaschromatograph) GhOST II (Gas Chromatograph for the Observation of Stratospheric Tracers) entwickelt und eingesetzt. Das Ziel dieser Messungen war die Untersuchung der jahreszeitlichen Variabilität der Spurengase in der oberen Troposphäre und untersten Stratosphäre (UT/LMS: Upper Troposphere/Lowermost Stratosphere), um die Transport- und Austauschprozesse in der Tropopausenregion besser zu verstehen. Zur Untersuchung von Transport und Mischung in der UT/LMS wurden die Rückwärtstrajektorien entlang der Flugpfade, die Verteilungen der Tracer N2O, F12, SF6, CO und CO2 (MPI für Chemie in Mainz), die Tracer/Tracer-Korrelationen N2O/F12, N2O/O3 F12/O3 und SF6/O3 und die Verteilungen des aus SF6-Messungen berechnete mittlere Alters der Luft herangezogen. Zusätzlich wurden die simultanen Messungen der beiden Alterstracer CO2 und SF6 genutzt, um die Propagation der Amplitude des troposphärischen CO2-Jahresgangs in die LMS zu bestimmen und daraus mit Hilfe eines empirischen Altersspektrums den Eintrag und die mittlere Transportzeit aus der Troposphäre in die unterste Stratosphäre zu quantifizieren. Grundsätzlich muss die LMS in zwei Bereiche eingeteilt werden – die Übergangsschicht („tropopause following layer“) bis etwa 20-30 K über der potentiellen Temperatur der lokalen Tropopause [Hoor et al., 2004] und die freie LMS oberhalb dieser Schicht. Als wesentliche Unterscheidungsmerkmale beider Bereiche wird die mittlere Transportzeit des Eintrags troposphärischer Luft identifiziert. Aus Trajektorienuntersuchungen und Tracerverteilungen (Kap. 3.4) kann gezeigt werden, dass der Transport in die Übergangsschicht und die Mischungsprozesse in diesem Bereich auf der Zeitskala der mesoskaligen troposphärischen Prozesse ablaufen. Im Gegensatz dazu werden aus der Massenbilanz (Kap. 5.3) mittlere Transportzeiten aus der Troposphäre in die freie LMS von einigen Wochen bis zu mehreren Monaten abgeleitet. Außerdem konnte nachgewiesen werden, dass der troposphärische Eintrag in der freien LMS fast ausschließlich auf quasihorizontale isentrope Einmischung aus den Tropen über die Transportbarriere des Subtropenjets zurückzuführen ist. Nur im Sommer und Herbst konnte auch oberhalb der Übergangsschicht für einzelne Messungen ein Einfluss aus der extratropischen Troposphäre beobachtet werden. Die in dieser Arbeit untersuchten Tracerverteilungen und -korrelationen (Kap. 4) und die Verteilung des mittleren Alters (Kap.5.2) in der LMS zeigen einen Jahresgang mit einem maximalen troposphärischen Einfluss im Oktober und einem maximalen stratosphärischen Einfluss im April. Diese saisonale Charakteristik in der freien LMS kann durch die saisonalen Änderungen des Verhältnisses von Abwärtstransport aus der Overworld und quasihorizontalem Transport aus den Tropen und durch die mit den jeweiligen Transportprozessen assoziierte mittlere Transportzeiten erklärt werden, die aus Massenbilanzrechnungen bestimmt wurden. Es wird gezeigt, dass der überwiegende Eintrag von troposphärischer Luft in die LMS im Sommer und Herbst stattfindet, wobei im Mittel die kürzesten mittleren Transitzeiten (unter 0.3 Jahre) für den August und die längsten Transitzeiten (über 0.6 Jahre) für den Mai berechnet werden. Aus den Ergebnissen wird gefolgert, dass ein ausgeprägter isentroper Austauschprozess über den Subtropenjet im Sommer bis in den Herbst hinein der dominierende troposphärische Einfluss in der LMS bis in den Mai ist. Der Vergleich zwischen SPURT und anderen in der UT/LMS im Zeitraum von 1992 bis 1998 durchgeführten Messkampagnen zeigt einen systematischen Unterschied in den N2O/O3-Korrelationen. Die Zunahme von O3 relativ zu N2O in der LMS ist um etwa 6.5 ppb O3 pro 1 ppb N2O bzw. etwa 40% größer als die Zunahme bei jahreszeitlich vergleichbaren früheren Kampagnen. Durch eine weitergehende Analyse der Messungen, z.B. durch den Vergleich der N2O-Verteilungen in der LMS bei verschiedenen Messkampagnen, und zusätzlichen Informationen aus Satelliten- und Ballonmessungen wird abgeleitet, dass diese Änderung der N2O/O3-Korrelationen im Wesentlichen auf einen im Zeitraum von SPURT stärkeren quasihorizontalen Transport aus den Tropen in die Extratropen im Bereich des so genannten „tropical controlled transition layer“ [Rosenlof et al., 1997] zwischen 16-21 km (bzw. Θ ≈ 380-450 K) zurückzuführen ist. In Kooperation mit B. Bregman wurden mit dem Chemie-Transport-Modell TM5 des KNMI die Verteilungen von SF6 und CO2 in der Troposphäre und Stratosphäre, unter den Zielsetzungen Evaluation des Modelltransports und Erweiterung des Datensatzes von SPURT auf globalen Maßstab, für den Zeitraum 1.1.2000 bis 31.12.2002 modelliert. Dabei konnte gezeigt werden, dass bei Modellstudien zur Evaluation des Transports mit Hilfe von Alterstracern nicht nur troposphärisch monoton steigende Tracer wie SF6 sondern auch saisonal variable Tracer wie CO2 verwendet werden müssen. Bei dem Vergleich der Modellergebnisse des TM5 mit ER2- und SPURTMessungen zeigt sich, dass das Modell zum jetzigen Zeitpunkt in der Lage ist, das mittlere Alter in der unteren Stratosphäre und die SF6- und CO2-Verteilungen in der LMS qualitativ richtig wiederzugeben. Das mittlere Alter in der unteren Stratosphäre wird um etwa 0.5 bis 1 Jahr in den Tropen über- und in den Extratropen unterschätzt. Die vertikalen Gradienten im Modell für SF6 und CO2 in der LMS sind, insbesondere im Winter und Frühjahr, zu gering. Die Amplitude des CO2-Jahresganges in der oberen Troposphäre und in der LMS wird durch das Modell unterschätzt, während der saisonale Verlauf des Jahresganges richtig wiedergegeben wird. Im Moment wird vermutet, dass eine zu starke isentrope Mischung zwischen Tropen und Extratropen und/oder ein zu geringer Aufwärtstransport in der extratropischen Troposphäre im Sommer und Herbst die Ursachen für die beobachteten Abweichungen zwischen Modell und Messung sind.
During SPURT (Spurenstofftransport in der Tropopausenregion, trace gas transport in the tropopause region) we performed measurements of a wide range of trace gases with different lifetimes and sink/source characteristics in the northern hemispheric upper troposphere (UT) and lowermost stratosphere (LMS). A large number of in-situ instruments were deployed on board a Learjet 35A, flying at altitudes up to 13.7 km, at times reaching to nearly 380 K potential temperature. Eight measurement campaigns (consisting of a total of 36 flights), distributed over all seasons and typically covering latitudes between 35° N and 75° N in the European longitude sector (10° W–20° E), were performed. Here we present an overview of the project, describing the instrumentation, the encountered meteorological situations during the campaigns and the data set available from SPURT. Measurements were obtained for N2O, CH4, CO, CO2, CFC12, H2, SF6, NO, NOy, O3 and H2O. We illustrate the strength of this new data set by showing mean distributions of the mixing ratios of selected trace gases, using a potential temperature – equivalent latitude coordinate system. The observations reveal that the LMS is most stratospheric in character during spring, with the highest mixing ratios of O3 and NOy and the lowest mixing ratios of N2O and SF6. The lowest mixing ratios of NOy and O3 are observed during autumn, together with the highest mixing ratios of N2O and SF6 indicating a strong tropospheric influence. For H2O, however, the maximum concentrations in the LMS are found during summer, suggesting unique (temperature- and convection-controlled) conditions for this molecule during transport across the tropopause. The SPURT data set is presently the most accurate and complete data set for many trace species in the LMS, and its main value is the simultaneous measurement of a suite of trace gases having different lifetimes and physical-chemical histories. It is thus very well suited for studies of atmospheric transport, for model validation, and for investigations of seasonal changes in the UT/LMS, as demonstrated in accompanying and elsewhere published studies.
During several balloon flights inside the Arctic polar vortex in early 2003, unusual trace gas distributions were observed, which indicate a strong influence of mesospheric air in the stratosphere. The tuneable diode laser (TDL) instrument SPIRALE (Spectroscopie InFrarouge par Absorption de Lasers Embarqués) measured unusually high CO values (up to 600 ppb) on 27 January at about 30 km altitude. The cryosampler BONBON sampled air masses with very high molecular Hydrogen, extremely low SF6 and enhanced CO values on 6 March at about 25 km altitude. Finally, the MIPAS (Michelson Interferometer for Passive Atmospheric Sounding) Fourier Transform Infra-Red (FTIR) spectrometer showed NOy values which are significantly higher than NOy* (the NOy derived from a correlation between N2O and NOy under undisturbed conditions), on 21 and 22 March in a layer centred at 22 km altitude. Thus, the mesospheric air seems to have been present in a layer descending from about 30 km in late January to 25 km altitude in early March and about 22 km altitude on 20 March. We present corroborating evidence from a model study using the KASIMA (KArlsruhe Simulation model of the Middle Atmosphere) model that also shows a layer of mesospheric air, which descended into the stratosphere in November and early December 2002, before the minor warming which occurred in late December 2002 lead to a descent of upper stratospheric air, cutting of a layer in which mesospheric air is present. This layer then descended inside the vortex over the course of the winter. The same feature is found in trajectory calculations, based on a large number of trajectories started in the vicinity of the observations on 6 March. Based on the difference between the mean age derived from SF6 (which has an irreversible mesospheric loss) and from CO2 (whose mesospheric loss is much smaller and reversible) we estimate that the fraction of mesospheric air in the layer observed on 6 March, must have been somewhere between 35% and 100%.
The total stratospheric organic chlorine and bromine burden was derived from balloon-borne measurements in the tropics (Teresina, Brazil, 5°04´ S, 42°52´ W) in 2005. Whole air samples were collected cryogenically at altitudes between 15 and 34 km. For the first time, we report measurements of a set of 28 chlorinated and brominated substances in the tropical upper troposphere and stratosphere including ten substances with an atmospheric lifetime of less than half a year. The substances were quantified using pre-concentration techniques followed by Gas Chromatography with Mass Spectrometric detection. In the tropical tropopause layer at altitudes between 15 and 17 km we found 1.1–1.4% of the chlorine and 6–8% of the bromine to be present in the form of very short-lived organic compounds. By combining the data with tropospheric reference data and age of air observations the abundances of inorganic chlorine and bromine (Cly and Bry) were derived. At an altitude of 34 km we calculated 3062 ppt of Cly and 17.5 ppt of Bry from the decomposition of both long- and short-lived organic source gases. Furthermore we present indications for the presence of additional organic brominated substances in the tropical upper troposphere and stratosphere.
The total stratospheric organic chlorine and bromine burden was derived from balloon-borne measurements in the tropics (Teresina, Brazil, 5°04´ S, 42°52´ W) in 2005. Whole air samples were collected cryogenically at altitudes between 15 and 34 km. For the first time, we report measurements of a set of 28 chlorinated and brominated substances in the tropical upper troposphere and stratosphere including ten substances with an atmospheric lifetime of less than half a year. The substances were quantified using pre-concentration techniques followed by Gas Chromatography with Mass Spectrometric detection. In the tropical tropopause layer at altitudes between 15 and 17 km we found 1.1–1.4% of the chlorine and 6–8% of the bromine to be present in the form of very short-lived organic compounds. By combining the data with tropospheric reference data and age of air observations the abundances of inorganic chlorine and bromine (Cly and Bry) were derived. At an altitude of 34 km we calculated 3062 ppt of Cly and 17.5 ppt of Bry from the decomposition of both long- and short-lived organic source gases. Furthermore we present indications for the presence of additional organic brominated substances in the tropical upper troposphere and stratosphere.
The seasonality of transport and mixing of air into the lowermost stratosphere (LMS) is studied using distributions of mean age of air and a~mass balance approach, based on in-situ observations of SF6 and CO2 during the SPURT (Spurenstofftransport in der Tropopausenregion, trace gas transport in the tropopause region) aircraft campaigns. Combining the information of the mean age of air and the water vapour distributions we demonstrate that the tropospheric air transported into the LMS above the extratropical tropopause layer (ExTL) originates predominantly from the tropical tropopause layer (TTL). The concept of our mass balance is based on simultaneous measurements of the two passive tracers and the assumption that transport into the LMS can be described by age spectra which are superposition of two different modes. Based on this concept we conclude that the stratospheric influence on LMS composition is strongest in April with tropospheric fractions (α1) below 20% and that the strongest tropospheric signatures are found in October with (α1 greater than 80%. Beyond the fractions, our mass balance concept allows to calculate the associated transit times for transport of tropospheric air from the tropics into the LMS. The shortest transit times (<0.3 years) are derived for the summer, continuously increasing up to 0.8 years by the end of spring. These findings suggest that strong quasi-horizontal mixing across the weak subtropical jet from summer to mid of autumn and the considerably shorter residual transport time-scales within the lower branch of the Brewer-Dobson circulation in summer than in winter dominates the tropospheric influence in the LMS until the beginning of next year's summer.
Fractional release factors of long-lived halogenated organic compounds in the tropical stratosphere
(2009)
Fractional release factors (FRFs) of organic trace gases are time-independent quantities that influence the calculation of Global Warming Potentials and Ozone Depletion Potentials. We present the first set of vertically resolved FRFs for 15 long-lived halo carbons in the tropical stratosphere up to 34 km altitude. They were calculated from measurements on air samples collected on board balloons and a high altitude aircraft. We compare the derived dependencies of FRFs on the mean stratospheric transit times (the so-called mean ages of air) with similarly derived FRFs originating from measurements at higher latitudes and find significant differences. Moreover a comparison with averaged FRFs currently used by the World Meteorological Organisation revealed the latter to be imprecise measures due to their observed vertical and latitudinal variability. The presented data set could thus be used to improve future ozone level and climate projections.
The seasonality of transport and mixing of air into the lowermost stratosphere (LMS) is studied using distributions of mean age of air and a mass balance approach, based on in-situ observations of SF6 and CO2 during the SPURT (Spurenstofftransport in der Tropopausenregion, trace gas transport in the tropopause region) aircraft campaigns. Combining the information of the mean age of air and the water vapour distributions we demonstrate that the tropospheric air transported into the LMS above the extratropical tropopause layer (ExTL) originates predominantly from the tropical tropopause layer (TTL). The concept of our mass balance is based on simultaneous measurements of the two passive tracers and the assumption that transport into the LMS can be described by age spectra which are superposition of two different modes. Based on this concept we conclude that the stratospheric influence on LMS composition is strongest in April with extreme values of the tropospheric fractions (alpha1) below 20% and that the strongest tropospheric signatures are found in October with alpha1 greater than 80%. Beyond the fractions, our mass balance concept allows us to calculate the associated transit times for transport of tropospheric air from the tropics into the LMS. The shortest transit times (<0.3 years) are derived for the summer, continuously increasing up to 0.8 years by the end of spring. These findings suggest that strong quasi-horizontal mixing across the weak subtropical jet from summer to mid of autumn and the considerably shorter residual transport time-scales within the lower branch of the Brewer-Dobson circulation in summer than in winter dominates the tropospheric influence in the LMS until the beginning of next year's summer.